Seed coat mediated resistance against Aspergillus flavus infection in peanut

IF 2.2 Q3 GENETICS & HEREDITY

Plant Gene Pub Date : 2022-12-01 DOI:10.1016/j.plgene.2022.100381

Lavanya Mendu , Christopher J. Cobos , Theophilus K. Tengey , Leslie Commey , Vimal K. Balasubramanian , Lindsay D. Williams , Kamalpreet K. Dhillon , Dimple Sharma , Manish K. Pandey , Hamidou Falalou , Rajeev K. Varshney , Mark D. Burow , Hari Kishan Sudini , Venugopal Mendu

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引用次数: 1

Abstract

Toxic metabolites known as aflatoxins are produced via certain species of the Aspergillus genus, specifically A. flavus, A. parasiticus, A. nomius, and A. tamarie. Although various pre- and post-harvest strategies have been employed, aflatoxin contamination remains a major problem within peanut crop, especially in subtropical environments. Aflatoxins are the most well-known and researched mycotoxins produced within the Aspergillus genus (namely Aspergillus flavus) and are classified as group 1 carcinogens. Their effects and etiology have been extensively researched and aflatoxins are commonly linked to growth defects and liver diseases in humans and livestock. Despite the known importance of seed coats in plant defense against pathogens, peanut seed coat mediated defenses against Aspergillus flavus resistance, have not received considerable attention. The peanut seed coat (testa) is primarily composed of a complex cell wall matrix consisting of cellulose, lignin, hemicellulose, phenolic compounds, and structural proteins. Due to cell wall desiccation during seed coat maturation, postharvest A. flavus infection occurs without the pathogen encountering any active genetic resistance from the live cell(s) and the testa acts as a physical and biochemical barrier only against infection. The structure of peanut seed coat cell walls and the presence of polyphenolic compounds have been reported to inhibit the growth of A. flavus and aflatoxin contamination; however, there is no comprehensive information available on peanut seed coat mediated resistance. We have recently reviewed various plant breeding, genomic, and molecular mechanisms, and management practices for reducing A. flavus infection and aflatoxin contamination. Further, we have also proved that seed coat acts as a physical and biochemical barrier against A. flavus infection. The current review focuses specifically on the peanut seed coat cell wall-mediated disease resistance, which will enable researchers to understand the mechanism and design efficient strategies for seed coat cell wall-mediated resistance against A. flavus infection and aflatoxin contamination.

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种皮介导花生对黄曲霉侵染的抗性

被称为黄曲霉毒素的有毒代谢物是通过曲霉属的某些种类产生的，特别是黄曲霉、寄生曲霉、野曲霉和塔玛丽曲霉。尽管采用了各种收获前和收获后的策略，黄曲霉毒素污染仍然是花生作物的主要问题，特别是在亚热带环境中。黄曲霉毒素是在曲霉属(即黄曲霉)中产生的最知名和研究最多的真菌毒素，被列为1类致癌物。它们的影响和病因已被广泛研究，黄曲霉毒素通常与人类和牲畜的生长缺陷和肝脏疾病有关。尽管已知种皮在植物防御病原体中的重要性，但花生种皮介导的对黄曲霉抗性的防御尚未得到相当大的重视。花生种皮主要由纤维素、木质素、半纤维素、酚类化合物和结构蛋白组成的复杂细胞壁基质组成。由于种皮成熟过程中细胞壁干燥，采收后黄曲霉感染发生时，病原体不会遇到活细胞的任何活性遗传抗性，而睾丸仅作为抵抗感染的物理和生化屏障。据报道，花生种皮细胞壁的结构和多酚类化合物的存在可以抑制黄曲霉和黄曲霉毒素污染的生长;然而，目前还没有关于花生种皮介导的抗性的全面资料。我们最近回顾了各种植物育种、基因组和分子机制以及减少黄曲霉感染和黄曲霉毒素污染的管理实践。此外，我们还证明种皮对黄曲霉感染具有物理和生化屏障作用。本文对花生种皮细胞壁介导的抗病性进行了综述，旨在了解花生种皮细胞壁介导的抗黄曲霉感染和黄曲霉毒素污染的机制和设计有效的策略。

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来源期刊

Plant Gene Agricultural and Biological Sciences-Plant Science

CiteScore

4.50

自引率

0.00%

发文量

审稿时长

51 days

期刊介绍： Plant Gene publishes papers that focus on the regulation, expression, function and evolution of genes in plants, algae and other photosynthesizing organisms (e.g., cyanobacteria), and plant-associated microorganisms. Plant Gene strives to be a diverse plant journal and topics in multiple fields will be considered for publication. Although not limited to the following, some general topics include: Gene discovery and characterization, Gene regulation in response to environmental stress (e.g., salinity, drought, etc.), Genetic effects of transposable elements, Genetic control of secondary metabolic pathways and metabolic enzymes. Herbal Medicine - regulation and medicinal properties of plant products, Plant hormonal signaling, Plant evolutionary genetics, molecular evolution, population genetics, and phylogenetics, Profiling of plant gene expression and genetic variation, Plant-microbe interactions (e.g., influence of endophytes on gene expression; horizontal gene transfer studies; etc.), Agricultural genetics - biotechnology and crop improvement.